CN114274265A - Numerical control door pocket cutting machining center - Google Patents

Numerical control door pocket cutting machining center Download PDF

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Publication number
CN114274265A
CN114274265A CN202210079678.8A CN202210079678A CN114274265A CN 114274265 A CN114274265 A CN 114274265A CN 202210079678 A CN202210079678 A CN 202210079678A CN 114274265 A CN114274265 A CN 114274265A
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China
Prior art keywords
assembly
frame
telescopic
door pocket
linear transmission
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CN202210079678.8A
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Chinese (zh)
Inventor
刘振
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Jiangsu Kangxun Cnc Equipment Technology Co ltd
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Jiangsu Kangxun Cnc Equipment Technology Co ltd
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Priority to CN202210079678.8A priority Critical patent/CN114274265A/en
Publication of CN114274265A publication Critical patent/CN114274265A/en
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Abstract

The invention discloses a numerical control door pocket cutting machining center, which comprises: a bed assembly; the bed body assembly adjusts the X and Z axial strokes of the plate and performs fixing operation; the upper part of the bed body assembly is provided with a gantry assembly through a sliding table assembly, and at least two groups of cutting saw assemblies are driven to perform stroke operation through the other group of sliding table assembly in a matched mode, so that a panel is cut; the cutting saw assembly is of a split structure; this device carries out mechanical linkage and mutually supports through gantry assembly collocation saw subassembly, can export the linear drive of the different axial of multiunit at the in-process of in-service use, the synchronous cooperation realizes carrying out self-adaptation interval adjustment and cutting operation to panel, can accomplish the automated production flow who adjusts the location, fluting explosion-proof limit, cutting broken edge at the in-process of in-service use, the actual required timber can be processed out to one time, effectively improve actual machining efficiency and accuracy, the degree of safety demand.

Description

Numerical control door pocket cutting machining center
Technical Field
The invention relates to the technical field of door pocket machining, in particular to a numerical control door pocket cutting machining center.
Background
The door pocket is a building decoration term and generally refers to two door frames inside and outside the door.
The sliding table saw and the electronic saw are mainly used in the current door pocket production, the labor cost is high, and the sliding table saw needs two persons to work in a cooperation mode. The thickness of the existing door pocket plate is generally tens of millimeters, and the existing door pocket plate is made of solid wood core materials, and one plate can reach 50 kilograms;
in the traditional processing technology, the door pocket is generally processed in batches in a manual operation mode. The manual processing can not work continuously for a long time, the processing efficiency is low, the requirement degree on the processing experience is high, and the actual practicability and the economic requirement are difficult to meet.
Therefore, a numerical control door pocket cutting machining center is provided.
Disclosure of Invention
In view of the above, the embodiments of the present invention are intended to provide a numerical control door pocket cutting machining center to solve or alleviate the technical problems in the prior art, and to provide at least one useful choice;
the technical scheme of the embodiment of the invention is realized as follows: numerical control door pocket cutting machining center includes: a bed assembly;
the bed body assembly adjusts the X and Z axial strokes of the plate and performs fixing operation;
the upper part of the bed body assembly is provided with a gantry assembly through a sliding table assembly, and at least two groups of cutting saw assemblies are driven to perform stroke operation through the other group of sliding table assembly in a matched mode, so that a panel is cut;
the cutting saw component is of a split structure and is at least matched with two cutters which are aligned with each other; the saw assembly enables linear adjustment of the cutter in the Y-axis, as well as the X or Z-axis.
As further preferable in the present technical solution: the bed body component comprises a frame, an adsorption platform, at least three first telescopic pieces and positioning pieces with the number corresponding to that of the first telescopic pieces;
the adsorption platform, the first telescopic piece and the positioning piece are all arranged on the upper surface of the rack, the first telescopic piece is arranged along an X axis or a Z axis, and a telescopic part of the first telescopic piece is used for adapting to and adjusting a plate and corresponds to the positioning piece;
the gantry assembly comprises a first frame body and a first linear transmission assembly;
the first linear transmission assembly is connected to the outside of the rack in a matched mode and drives the first rack body to conduct linear adjustment along the length direction of the rack.
As further preferable in the present technical solution: the cutting and sawing assembly comprises a second linear transmission assembly, a second telescopic piece, a first frame body assembly, a second frame body assembly and a third telescopic piece;
the first frame body assembly and the second frame body assembly are formed by mutually connecting at least two plate bodies in a sliding manner;
the sliding table assembly on the upper part of the gantry assembly is mutually and slidably connected with the first frame body assembly, and the first frame body is mutually connected with a plate body of the first frame body assembly through the second linear transmission assembly and carries out linear transmission;
the second telescopic piece is arranged on the other plate body of the first frame body assembly, and a telescopic part of the second telescopic piece is matched with and drives the first frame body assembly to be linearly adjusted;
the first frame assembly is connected with the cutter, and the second frame assembly is connected with the cutter;
install between the second support body subassembly the third extensible member, the third extensible member is used for the drive adjust between the second support body subassembly.
As further preferable in the present technical solution: and a cover body is arranged outside the first frame body assembly and corresponds to the cutter.
As further preferable in the present technical solution: replacing the second telescoping member with a third linear drive assembly;
first support body subassembly is formed by the mutual sliding connection combination of three plate body at least, the third linear transmission subassembly is used for the drive the rear portion and the middle part plate body of first support body subassembly carry out linear transmission, the third extensible member install in the anterior plate body of first support body subassembly, and be used for the drive the cutterbar carries out Y axial linear regulation.
As further preferable in the present technical solution: the first telescopic piece, the second telescopic piece and the third telescopic piece are first air cylinders or servo electric cylinders;
the first linear transmission assembly, the second linear transmission assembly and the third linear transmission assembly comprise a motor, a gear arranged on an output shaft of the motor, and a rack engaged with gear teeth of the gear; or a ball screw driven by the output shaft of the motor and a moving nut linearly fitted on the threaded rod thereof;
the cutter includes a saw disc driven by a saw blade spindle.
Numerical control door pocket is opened material machining center's material actuating mechanism that send and is put includes: the carrying mechanism is arranged at two ends of the gantry assembly;
the carrying mechanism comprises a second frame body and a sucker assembly;
the sucker assemblies are arranged along the Y axis and are uniformly distributed to the front part, the rear part and the two side surfaces of the second frame body for adsorbing plates.
As further preferable in the present technical solution: the sucking disc subassembly includes the sucking disc ware that second cylinder and be connected with its piston rod.
As further preferable in the present technical solution: the upper part of the carrying mechanism is provided with a dust collection assembly;
the dust collection assembly comprises a dust collection box and a fourth telescopic piece for driving the dust collection box to be adjusted up and down.
As further preferable in the present technical solution: the fourth telescopic member is a third cylinder.
Compared with the prior art, the invention has the beneficial effects that:
the device carries out mechanical linkage and mutual matching through the matching of the gantry assembly and the cutting and sawing assembly, can output a plurality of groups of linear transmissions in different axial directions in the actual use process, realizes self-adaptive interval adjustment and cutting operation on plates in synchronous matching, can complete the automatic production processes of adjusting and positioning, slotting and edge explosion prevention and cutting edge breakage in the actual use process, can process actually required wood at one time, and effectively improves the actual processing efficiency, accuracy and safety requirement;
the device carries out mechanical linkage and mutual matching through the bed body assembly and the carrying mechanism, can carry out positioning and fixing operation aiming at plates with different sizes and different models in the actual use process, and realizes quick positioning and cutting by matching with the cutting and sawing assembly, thereby effectively improving the actual processing efficiency and the requirements on accuracy and safety;
the device is integrally designed in a modularized mode, can be conveniently operated in installation, use and routine maintenance, meets the requirements of cost and practicability, can be produced in large scale, and effectively meets the requirements of current actual use.
Drawings
In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the embodiments or technical descriptions will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.
FIG. 1 is a schematic perspective view of the present invention;
FIG. 2 is a schematic perspective view of the present invention;
FIG. 3 is a schematic perspective view of the bed assembly of the present invention;
FIG. 4 is a schematic perspective view of a gantry assembly of the present invention;
FIG. 5 is a perspective view of the saw assembly of the present invention;
FIG. 6 is a perspective view of another embodiment of the saw assembly of the present invention;
FIG. 7 is a schematic view of another embodiment of the saw assembly of the present invention;
FIG. 8 is a perspective view of the carrying mechanism of the present invention;
FIG. 9 is a perspective view of the cleaning assembly of the present invention;
FIG. 10 is a top view of the adsorption platform of the present invention.
Reference numerals: 1. a bed assembly; 101. a frame; 102. an adsorption platform; 103. a first telescoping member; 104. a positioning member; 2. a gantry assembly; 201. a first frame body; 202. a first linear drive assembly; 3. a saw assembly; 301. a second linear drive assembly; 302. a cutter; 303. a second telescoping member; 304. a first frame assembly; 305. a cover body; 306. a second frame assembly; 307. a third telescoping member; 4. a third linear drive assembly; 5. a carrying mechanism; 501. a second frame body; 502. a sucker component; 6. a dust collection assembly; 601. a dust collection box; 602. and a fourth telescoping member.
Detailed Description
In the following, only certain exemplary embodiments are briefly described. As those skilled in the art will recognize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. Accordingly, the drawings and description are to be regarded as illustrative in nature, and not as restrictive.
It should be noted that the terms "first", "second", "symmetrical", "array", and the like are used for descriptive and positional purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first," "symmetrical," etc., may explicitly or implicitly include one or more of that feature; similarly, where a feature is not limited in number to "two," "three," etc., it is noted that the feature likewise explicitly or implicitly includes one or more feature numbers;
in the present invention, unless otherwise expressly specified or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly; for example, the connection can be fixed, detachable or integrated; the connection may be mechanical, direct, welded, indirect via an intermediate medium, communication between two elements, or interaction between two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art from the specification and drawings in combination with the specific situation.
Example one
Referring to fig. 1-9, the present invention provides a technical solution: numerical control door pocket cutting machining center includes: a bed assembly 1;
the bed body component 1 adjusts the X and Z axial positions of the plate and performs fixing operation;
the upper part of the bed body component 1 is provided with a gantry component 2 through a sliding table component, and the other sliding table component (area A in the figure) is used for driving two groups of cutting saw components 3 to perform stroke operation in a matching way, so that a panel is cut;
the cutting and sawing component 3 is of a split structure and is matched with two mutually aligned cutters 302; the saw assembly 3 enables linear adjustment of the cutter 302 in the Y-axis direction, as well as in the X or Z-axis direction.
In this embodiment, please refer to fig. 1: a feeder (area D in the figure) is arranged at the front part of the bed body component 1 and is responsible for feeding a plate (area E in the figure) onto the rack 101;
the rear part of the bed body component 1 is provided with a conveyor (F area in the figure) for conveying the processed plates to the outside.
In this embodiment, please refer to fig. 3: the bed body component 1 comprises a frame 101, an adsorption platform 102, three first telescopic pieces 103 and positioning pieces 104 with the number corresponding to that of the first telescopic pieces;
the adsorption platform 102, the first telescopic piece 103 and the positioning piece 104 are all installed on the upper surface of the rack 101, the first telescopic piece 103 is arranged along an X axis or a Z axis, and the telescopic part of the first telescopic piece 103 is used for adapting and adjusting a plate and corresponds to the positioning piece 104;
the gantry assembly 2 comprises a first frame 201 and a first linear transmission assembly 202;
the first linear transmission assembly 202 is connected to the outside of the rack 101 in a matching manner and drives the first frame body 201 to perform linear adjustment along the length direction of the rack 101;
the first telescopic piece 103 pushes and fastens the periphery of the plate by matching with the corresponding positioning piece 104, and the adsorption platform 102 fixes the plate;
the first linear transmission assembly 202 is matched with the first frame body 201 to adjust the position (X-axis or Z-axis) thereof so as to adapt the cutting saw assembly 3 to perform cutting operation.
In this embodiment, please refer to fig. 10: the adsorption platform 102 is electrically controlled, partitions are reasonably divided according to a door pocket machining process, the electromagnetic valve and the hole body shown in the S area in the drawing are matched to divide the adsorption area into control adsorption areas with different sizes, the plate does not need to be adsorbed in the area after cutting, the electromagnetic valve is automatically controlled by an external controller to close vacuum adsorption of the area, and centralized adsorption of the plate is achieved.
In the present embodiment, please refer to fig. 5 to 6: the cutting saw assembly 3 comprises a second linear transmission assembly 301, a second telescopic member 303, a first frame assembly 304, a second frame assembly 306 and a third telescopic member 307;
the first frame assembly 304 and the second frame assembly 306 are formed by two plates which are connected with each other in a sliding manner;
the sliding table assembly at the upper part of the gantry assembly 2 is connected with the first frame body assembly 304 in a sliding manner, and the first frame body 201 and a plate body of the first frame body assembly 304 are connected with each other through the second linear transmission assembly 301 and perform linear transmission;
the second telescopic member 303 is mounted on the other plate of the first frame assembly 304, and the telescopic part of the second telescopic member 303 is matched with and drives the first frame assembly 304 to perform linear adjustment;
one cutter 302 is mounted on the outside of the first frame assembly 304 and is cooperatively connected with a second frame assembly 306, the second frame assembly 306 is cooperatively connected with another cutter 302;
third telescopic pieces 307 are arranged between the second frame assemblies 306, and the third telescopic pieces 307 are used for being matched with the second frame assemblies 306 to perform self-adaptive adjustment so as to match plates with different thicknesses according to actual conditions;
the first telescopic piece 103, the second telescopic piece 303 and the third telescopic piece 307 are first air cylinders or servo electric cylinders;
the first linear transmission assembly 202, the second linear transmission assembly 301 and the third linear transmission assembly 4 comprise a motor, a gear installed on an output shaft of the motor, and a rack engaged with teeth of the gear;
cutter 302 includes a saw disc driven by a blade spindle;
the second linear transmission assembly 301 is used for matching with the gantry assembly 2 and adjusting the position of the whole cutting saw assembly 3 along the X axis or the Z axis;
the second telescopic part 303 drives the first frame assembly 304 to perform Y-axis single-line adjustment, and is adapted to drive the two groups of cutters 302 to perform lifting operation;
the cutter 302 at the front performs explosion-proof edge cutting on the plate in advance, and the stroke ratio of the cutter is realized by lifting and adjusting the second frame assembly 306 through the third telescopic piece 307;
after the front cutter 302 cuts the explosion-proof edge of the plate, the rear cutter 302 cuts the plate completely along the explosion-proof edge.
In this embodiment, specifically: a cover 305 is mounted on the exterior of the first frame assembly 304 and corresponds to the cutter 302;
a dust suction port is provided in the cover body 305, and the cutter 302 throws saw dust or dust toward the dust suction port by a rotational force during cutting to perform a dust suction operation.
In the present embodiment, please refer to fig. 5 to 6: the area B in the figure is rotatably connected with four rubber coating wheels, and in the process of displacement of the cutting saw component 3, the rubber coating wheels are matched with the third telescopic piece 307 to realize adjustment and adaptation operation on plates with different thicknesses, so that the consistency of cutting of the explosion-proof edge is guaranteed.
In this embodiment, specifically: the sliding table assembly comprises a sliding block and a sliding rail which are in sliding fit with each other.
Example two
Referring to fig. 1-9, the present invention provides a technical solution: numerical control door pocket cutting machining center includes: a bed assembly 1;
the bed body component 1 adjusts the X and Z axial positions of the plate and performs fixing operation;
the upper part of the bed body component 1 is provided with a gantry component 2 through a sliding table component, and the other sliding table component (area A in the figure) is used for driving two groups of cutting saw components 3 to perform stroke operation in a matching way, so that a panel is cut;
the cutting and sawing component 3 is of a split structure and is matched with two mutually aligned cutters 302; the saw assembly 3 enables linear adjustment of the cutter 302 in the Y-axis direction, as well as in the X or Z-axis direction.
In this embodiment, please refer to fig. 1: a feeder (area D in the figure) is arranged at the front part of the bed body component 1 and is responsible for feeding a plate (area E in the figure) onto the rack 101;
the rear part of the bed body component 1 is provided with a conveyor (F area in the figure) for conveying the processed plates to the outside.
In this embodiment, please refer to fig. 3: the bed body component 1 comprises a frame 101, an adsorption platform 102, three first telescopic pieces 103 and positioning pieces 104 with the number corresponding to that of the first telescopic pieces;
the adsorption platform 102, the first telescopic piece 103 and the positioning piece 104 are all installed on the upper surface of the rack 101, the first telescopic piece 103 is arranged along an X axis or a Z axis, and the telescopic part of the first telescopic piece 103 is used for adapting and adjusting a plate and corresponds to the positioning piece 104;
the gantry assembly 2 comprises a first frame 201 and a first linear transmission assembly 202;
the first linear transmission assembly 202 is connected to the outside of the rack 101 in a matching manner and drives the first frame body 201 to perform linear adjustment along the length direction of the rack 101;
the first telescopic piece 103 pushes and fastens the periphery of the plate by matching with the corresponding positioning piece 104, and the adsorption platform 102 fixes the plate;
the first linear transmission assembly 202 is matched with the first frame body 201 to adjust the position (X-axis or Z-axis) thereof so as to adapt the cutting saw assembly 3 to perform cutting operation.
In this embodiment, please refer to fig. 10: the adsorption platform 102 is electrically controlled, partitions are reasonably divided according to a door pocket machining process, the electromagnetic valve and the hole body shown in the S area in the drawing are matched to divide the adsorption area into control adsorption areas with different sizes, the plate does not need to be adsorbed in the area after cutting, the electromagnetic valve is automatically controlled by an external controller to close vacuum adsorption of the area, and centralized adsorption of the plate is achieved.
In this embodiment, please refer to fig. 7: the cutting saw assembly 3 comprises a second linear transmission assembly 301, a second telescopic member 303, a first frame assembly 304, a second frame assembly 306 and a third telescopic member 307;
the first frame assembly 304 and the second frame assembly 306 are formed by two plates which are connected with each other in a sliding manner;
the sliding table assembly at the upper part of the gantry assembly 2 is connected with the first frame body assembly 304 in a sliding manner, and the first frame body 201 and a plate body of the first frame body assembly 304 are connected with each other through the second linear transmission assembly 301 and perform linear transmission;
the second telescopic member 303 is mounted on the other plate of the first frame assembly 304, and the telescopic part of the second telescopic member 303 is matched with and drives the first frame assembly 304 to perform linear adjustment;
one cutter 302 is mounted on the outside of the first frame assembly 304 and is cooperatively connected with a second frame assembly 306, the second frame assembly 306 is cooperatively connected with another cutter 302;
the first frame assembly 304 is formed by mutually and slidably connecting and combining three plates, the third linear transmission assembly 4 is used for driving the rear part and the middle plate of the first frame assembly 304 to perform linear transmission, and the third telescopic member 307 is mounted on the front plate of the first frame assembly 304 and used for driving the cutter 302 to perform Y-axis linear adjustment;
the first telescopic piece 103, the second telescopic piece 303 and the third telescopic piece 307 are first air cylinders or servo electric cylinders;
the first linear transmission assembly 202, the second linear transmission assembly 301 and the third linear transmission assembly 4 comprise a motor, a ball screw driven by an output shaft of the motor, and a moving nut linearly fitted on a threaded rod thereof;
cutter 302 includes a saw disc driven by a blade spindle;
in this embodiment, specifically: the third linear transmission assembly 4 is connected with the ball screw through a motor matching coupler.
The second linear transmission assembly 301 is used for matching with the gantry assembly 2 and adjusting the position of the whole cutting saw assembly 3 along the X axis or the Z axis;
the third linear transmission assembly 4 drives the first frame assembly 304 to perform Y-axis bilinear adjustment, the stroke ratio and the shock resistance requirement are improved through thread pair transmission, and the two groups of cutters 302 are driven to perform lifting operation in an adaptive manner;
the cutter 302 at the front performs explosion-proof edge cutting on the plate in advance, and the stroke ratio of the cutter is realized by lifting and adjusting the second frame assembly 306 through the third telescopic piece 307;
after the front cutter 302 cuts the explosion-proof edge of the plate, the rear cutter 302 cuts the plate completely along the explosion-proof edge.
In this embodiment, please refer to fig. 7: the B district in the figure rotates and is connected with four rubber coating wheels, and during the process that saw subassembly 3 carries out the displacement, rubber coating wheel cooperation third extensible member 307 realizes adjusting the panel of different thickness and adaptation operation, the uniformity of guarantee explosion-proof limit cutting.
In this embodiment, specifically: a cover 305 is mounted on the exterior of the first frame assembly 304 and corresponds to the cutter 302;
a dust suction port is provided in the cover body 305, and the cutter 302 throws saw dust or dust toward the dust suction port by a rotational force during cutting to perform a dust suction operation.
Numerical control door pocket is opened material machining center's material actuating mechanism that send and is put includes: the carrying mechanism 5 is arranged at two ends of the gantry assembly 2;
the carrying mechanism 5 comprises a second frame 501 and a sucker assembly 502;
the sucker assemblies 502 are arranged along the Y axis, and are uniformly distributed at the front, back and two side surfaces of the second frame body 501 for adsorbing the plates; the sucker assembly 502 comprises a second cylinder and a sucker connected with a piston rod of the second cylinder;
in the sucker assembly 502, stroke adjustment is performed through a second air cylinder, and a plate is fastened and pressed by matching with a sucker, so that cutting requirements are met;
and the carrying mechanism 5 can be adapted and adjusted during the position movement of the gantry assembly 2.
In this embodiment, please refer to fig. 9: the upper part of the carrying mechanism 5 is provided with a dust collection assembly 6;
the dust collection assembly 6 comprises a dust collection box 601 and a fourth telescopic piece 602 for driving the dust collection box to adjust up and down; the fourth telescoping piece 602 is a third cylinder;
the third cylinder drives the dust collection box 601 to lift, and an opening (a C area in the drawing) at the lower part of the dust collection box can be matched with the dust collection box to perform dust collection operation;
the dust collection box 601 is a power element, and the interior of the dust collection box is composed of an air pump and an air duct.
In this embodiment, specifically: the sliding table assembly comprises a sliding block and a sliding rail which are in sliding fit with each other.
In this embodiment, specifically: the whole electrical components of the device are powered by mains supply.
In this embodiment, specifically: the whole electrical components of the device are automatically controlled by an external controller.
In this embodiment, specifically: the whole pneumatic element of the device is controlled by an electromagnetic valve and a control console, and the air is supplied by an external air storage tank.
Working principle or structural principle: in the bed assembly 1 and the gantry assembly 2, the first linear transmission assembly 202 is connected to the outside of the frame 101 in a matching manner and drives the first frame body 201 to perform linear adjustment along the length direction of the frame 101;
the first telescopic piece 103 pushes and fastens the periphery of the plate by matching with the corresponding positioning piece 104, and the adsorption platform 102 fixes the plate;
the first linear transmission assembly 202 is matched with the first frame body 201 to adjust the position (X axis or Z axis) of the first linear transmission assembly; in the carrying mechanism 5, stroke adjustment is carried out through a second air cylinder, and the plate is fastened and pressed by matching with a sucker so as to be matched with the cutting saw component 3 for cutting operation;
the second linear transmission assembly 301 is used for matching with the gantry assembly 2 and adjusting the position of the whole cutting saw assembly 3 along the X axis or the Z axis;
the third linear transmission assembly 4 drives the first frame assembly 304 to perform Y-axis bilinear adjustment, the stroke ratio and the shock resistance requirement are improved through thread pair transmission, and the two groups of cutters 302 are driven to perform lifting operation in an adaptive manner;
the cutter 302 at the front performs explosion-proof edge cutting on the plate in advance, and the stroke ratio of the cutter is realized by lifting and adjusting the second frame assembly 306 through the third telescopic piece 307;
after the front cutter 302 cuts the explosion-proof edge of the plate, the rear cutter 302 cuts the plate completely along the explosion-proof edge.
The above description is only for the specific embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive various changes or substitutions within the technical scope of the present invention, and these should be covered by the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the appended claims.

Claims (10)

1. Numerical control door pocket cutting machining center, its characterized in that includes: a bed assembly (1);
the bed body component (1) adjusts the X and Z axial strokes of the plate and performs fixing operation;
the gantry assembly (2) is mounted on the upper portion of the bed body assembly (1) through a sliding table assembly, at least two groups of cutting saw assemblies (3) are driven to perform stroke operation in a matched mode through the other group of sliding table assembly, and plates are cut;
the cutting and sawing component (3) is of a split structure and is at least matched with two cutters (302) which are aligned with each other; the cutting and sawing assembly (3) can perform linear adjustment on the cutter (302) in a Y-axis direction and an X-axis direction or a Z-axis direction.
2. The numerical control door pocket cutting machining center according to claim 1, characterized in that: the bed body assembly (1) comprises a rack (101), an adsorption platform (102), at least three first telescopic pieces (103) and positioning pieces (104) with the number corresponding to that of the first telescopic pieces;
the adsorption platform (102), the first telescopic piece (103) and the positioning piece (104) are all installed on the upper surface of the rack (101), the first telescopic piece (103) is arranged along an X axis or a Z axis, and a telescopic part of the first telescopic piece (103) is used for adapting to and adjusting a plate and corresponds to the positioning piece (104);
the gantry assembly (2) comprises a first frame body (201) and a first linear transmission assembly (202);
the first linear transmission assembly (202) is connected to the outside of the rack (101) in a matched mode and drives the first rack body (201) to conduct linear adjustment along the length direction of the rack (101).
3. The numerical control door pocket cutting machining center according to claim 2, characterized in that: the cutting and sawing assembly (3) comprises a second linear transmission assembly (301), a second telescopic piece (303), a first frame body assembly (304), a second frame body assembly (306) and a third telescopic piece (307);
the first frame assembly (304) and the second frame assembly (306) are formed by mutually connecting at least two plate bodies in a sliding manner;
the sliding table assembly at the upper part of the gantry assembly (2) is connected with the first frame body assembly (304) in a sliding manner, and the first frame body (201) is connected with a plate body of the first frame body assembly (304) through the second linear transmission assembly (301) and performs linear transmission;
the second telescopic piece (303) is mounted on the other plate body of the first frame body assembly (304), and a telescopic part of the second telescopic piece (303) is matched with and drives the first frame body assembly (304) to be linearly adjusted;
one of the cutters (302) is mounted to an exterior of the first frame assembly (304) and is cooperatively coupled with the second frame assembly (306), and the second frame assembly (306) is cooperatively coupled with another of the cutters (302);
install between second support body subassembly (306) third extensible member (307), third extensible member (307) are used for the drive adjust between second support body subassembly (306).
4. The numerical control door pocket cutting machining center according to claim 3, characterized in that: a cover body (305) is arranged outside the first frame body assembly (304) and corresponds to the cutter (302).
5. The numerical control door pocket cutting machining center according to claim 3, characterized in that: replacing the second telescopic member (303) with a third linear transmission assembly (4);
the first frame assembly (304) is formed by at least combining three plate bodies in a sliding connection mode, the third linear transmission assembly (4) is used for driving the rear portion and the middle plate body of the first frame assembly (304) to perform linear transmission, and the third telescopic piece (307) is installed on the front plate body of the first frame assembly (304) and used for driving the cutter (302) to perform Y-axis linear adjustment.
6. The numerical control door pocket cutting machining center according to claim 4, characterized in that: the first telescopic piece (103), the second telescopic piece (303) and the third telescopic piece (307) are first air cylinders or servo electric cylinders;
the first linear transmission assembly (202), the second linear transmission assembly (301) and the third linear transmission assembly (4) comprise a motor, a gear mounted on an output shaft of the motor, and a rack engaged with gear teeth of the gear; or a ball screw driven by the output shaft of the motor and a moving nut linearly fitted on the threaded rod thereof;
the cutter (302) includes a saw disc driven by a saw blade spindle.
7. Numerical control door pocket is opened material machining center's material actuating mechanism that send and is put, its characterized in that includes: the device comprises a carrying mechanism (5) and a gantry assembly (2), wherein the carrying mechanism (5) is arranged at two ends of the gantry assembly (2);
the carrying mechanism (5) comprises a second frame body (501) and a sucker assembly (502);
the sucker assemblies (502) are arranged along the Y axis, and are uniformly distributed at the front part, the rear part and two side surfaces of the second frame body (501) and used for adsorbing plates.
8. The feeding and discharging driving mechanism of the numerical control door pocket cutting machining center according to claim 7, characterized in that: the sucker component (502) comprises a second air cylinder and a sucker connected with a piston rod of the second air cylinder.
9. The feeding and discharging driving mechanism of the numerical control door pocket cutting machining center according to claim 7 or 8, characterized in that: the upper part of the carrying mechanism (5) is provided with a dust collection assembly (6);
the dust collection assembly (6) comprises a dust collection box (601) and a fourth telescopic piece (602) for driving the dust collection box to adjust up and down.
10. The feeding and discharging driving mechanism of the numerical control door pocket cutting machining center according to claim 9, characterized in that: the fourth telescoping piece (602) is a third cylinder.
CN202210079678.8A 2022-01-24 2022-01-24 Numerical control door pocket cutting machining center Pending CN114274265A (en)

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CN202210079678.8A CN114274265A (en) 2022-01-24 2022-01-24 Numerical control door pocket cutting machining center

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CN115534028A (en) * 2022-10-28 2022-12-30 江苏康迅数控装备科技有限公司 Machining center of row-type tool magazine cutting machine
CN115533590A (en) * 2022-10-21 2022-12-30 江苏康迅数控装备科技有限公司 Disc tool magazine type tool changing and cutting machining center

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CN111730695A (en) * 2020-07-22 2020-10-02 济南品嘉机械设备有限公司 Woodworking double-gantry numerical control engraving machine and working method
CN215358891U (en) * 2021-07-20 2021-12-31 郭奕辉 Portal frame for numerical control cutting machine
CN217098109U (en) * 2022-01-24 2022-08-02 江苏康迅数控装备科技有限公司 Numerical control door pocket cutting machining center

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CN211030386U (en) * 2019-09-24 2020-07-17 山东宏大博刻智能装备有限公司 Wood processing equipment with saw blade and milling cutter capable of being automatically switched
CN111730695A (en) * 2020-07-22 2020-10-02 济南品嘉机械设备有限公司 Woodworking double-gantry numerical control engraving machine and working method
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CN217098109U (en) * 2022-01-24 2022-08-02 江苏康迅数控装备科技有限公司 Numerical control door pocket cutting machining center

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CN115533590A (en) * 2022-10-21 2022-12-30 江苏康迅数控装备科技有限公司 Disc tool magazine type tool changing and cutting machining center
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